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1、IEEE Std 1276, 2000 Edition IEEE Guide for the Application of High- Temperature Insulation Materials in Liquid-Immersed Power Transformers Sponsor Transformer Committee of the IEEE Power Engineering Society Approved 30 March 2000 IEEE Standards Board Previously approved as a trial-use guide Approved
2、 26 June 1997 IEEE Standards Board Abstract: Technical information is provided related to liquid-immersed power transformers insulated with high-temperature materials. Guidelines for applying existing qualified high- temperature materials to certain insulation systems, recommendations for loading hi
3、gh- temperature liquid-immersed power transformers, and technical information on insulation-system temperature ratings and test procedures for qualifying new high-temperature materials are included. Keywords: high-temperature insulation material, hybrid insulation system, liquid-immersed power trans
4、former, loadinci wide The Institute of Electrical and Electronics Engineers, Inc 345 East 47th Street, NewYork, NY 10017-2394, USA Copyright O 2000 by the Institute of Electrical and Electronics Engineers, Inc. All rights reserved. Published 1997. Printed in the United States of America. Print: ISBN
5、 0-7381-2996-8 PDF: ISBN 0-7381-2997-6 No pad of fhis pubkafion may be reproduced in any form, in an elecfronic re frieval sysfem or ofherwise, wihouf fhe prior wriien permission of fhe pubkshe/: IEEE Standards documents are developed within the IEEE Societies and the Standards Coordinating Commit-
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20、egal validity or scope of those patents that are brought to its attention. IEEE is the sole entity that may authorize the use of certification marks, trademarks, or other designations to indi- cate compliance with the materials set forth herein. Authorization to photocopy portions of any individual
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22、od Drive, Danvers, MA 01923 USA; +1 978 750 8400. Permission to photocopy portions of any indi- vidual standard for educational classroom use can also be obtained through the Copyright Clearance Center. -,-,- I n t rod u ct ion (This introduction is not part of IEEE Std 1276, 2000 Edition, IEEE Guid
23、e for the Application of High- Temperature Insulation Materials in Liquid-Immersed Power Transformers.) Liquid-immersed transformers utilizing high-temperature insulation systems are being used increasingly by the industry, and current standards do not effectively cover their performance criteria. T
24、his guide is intended to give the user some background information on the application and use of high-temperature insulation in power transformers. The highest allowable temperature of the transformer winding insulation is an essential parameter in determining the maximum load that a transformer may
25、 reliably carry. If the allowable winding hottest-spot temperature may be increased, the weight and size of a power transformer may be significantly reduced while maintaining the same rated power, or, for the same size unit, the allowable power output may be increased. However, the user must underst
26、and the consequences of allowing the transformer temperature to exceed the materials accepted limits. The operating life of conventional insulating materials-namely, paper, transformerboard, and mineral oil-is dependent upon the operating temperature and the contaminants, including moisture, in the
27、transformer. Existing transformer standards specify the maximum allowable winding hottest-spot temperature on the basis of an acceptable normal insulation life. A relationship between temperature and degradation of the dielectric insulation has been established in IEEE Std C57.91-1995. From this rel
28、ationship, the loss of insulation life due to a temporary or permanent loading beyond normal operating temperatures may be calculated. The actual life of a transformer depends only indirectly on the thermal aging of solid insulation materials. Laboratory tests of cellulose materials (i.e., paper and
29、 transformerboard) have demonstrated that overheating can significantly reduce their tensile strength with only a slight reduction in dielectric strength. Therefore, a likely failure mode caused by overheating of the cellulose is the mechanical breakdown of embrittled insulation during a high-curren
30、t fault, which can lead to a dielectric breakdown of the damaged insulation. This phenomenon may hold for other insulating materials as well. One method of reducing the weight and size of a liquid-immersed transformer without sacrificing its life or reliability is the use of materials with higher te
31、mperature capability. The rst step in this direction was made some 40 years ago when thermally upgraded cellulose was developed for transformer insulation. This technological improvement increased the rated power of liquid-immersed transformers by 12%, allowing the average winding rise to increase f
32、rom 55 “C to 65 “C.* During the last 30 years, materials with even higher temperature capability, such as aramid papers and transformerboards and high-temperature enamels, have been developed. To date, these materials have been used in some specialty transformers, such as traction or mobile units, a
33、nd some have been used to uprate liquid-immersed transformers rebuilt after a failure. There are potential applications for new transformers using these high-temperature insulation materials. For example, instead of installing a cellulosic-insulated transformer with a rating equal to the overloads,
34、a smaller-rated unit with high-temperature insulation materials can be installed that can withstand the desired overload. It is important to note that high-temperature insulation materials must meet a number of criteria to be suitable for use in power transformers. They must operate at elevated temp
35、eratures in transformer oil while maintaining their mechanical and dielectric properties. They must also demonstrate compatibility with all other components of the transformer, as well as have suitable characteristics for the mechanical stresses encountered in a power transformer, such as adequate c
36、ompressive strength. *Discussions of 55 “C rise systems are included in this guide for historical reference only. Copyright O 2000 IEEE. All rights reserved. . 1 1 1 -,-,- Combining high-temperature and cellulosic materials to form a hybrid high-temperature insulation system is another viable option
37、. This hybrid insulation system is usually composed of high-temperature materials adjacent to winding conductors, where temperatures are hottest, with cellulose-based materials in other areas. This insulation system is possible because only insulation material in direct contact with the winding cond
38、uctors, and perhaps the core, is exposed to the highest temperatures, while other parts of the insulation system operate at lower temperatures. To date, only aramid papers, aramid transformerboards, and high- temperature enamels in combination with cellulose have been used in this type of hybrid ins
39、ulation system. From the point of view of thermal aging, cellulose has been the limiting factor of traditional insulation systems composed of mineral oil, cellulose, and enamel. With the advent of high-temperature solid insulating materials, mineral oil becomes the limiting factor, establishing the
40、highest allowable temperature of the insulation system. Other insulating fluids have been examined for the possible replacement of mineral oil, and many are used in applications where their dielectric and physical properties meet the needs of those applications. Until now there have been few instanc
41、es where these other insulating fluids have been used in power transformers above 30 MVA. Certain fluids, such as silicones, high molecular weight hydrocarbons, non-PCB chlorinated hydrocarbons, polyolens, and ester-based fluids, may offer particular advantageous characteristics for specific applica
42、tions. Future research may identify new fluids with broader applications for use in power transformers that can operate at higher temperatures due to high-temperature insulating materials. Other factors to consider when designing units that operate at high temperatures are, for example, load losses,
43、 tap changers, bushings, control wiring, paint, and adhesives. Part ici pants At the time this guide was completed, the Working Group on High-Temperature Insulation for Liquid- Immersed Power Transformers had the following membership: J. Arteaga J. Aubin R. L. Barker M. F. Barnes D. Chu J. L. Corkra
44、n V. Dahinden R. C. Degeneff D. Dohnal M. L. Frazier D. F. Goodwin J. L. Goudie R. L. Grubb P. J. Hopkinson V. C. Jhonsa E. W. Kalkstein C. J. Kalra Michael A. Franche& Chair L. Koga B. Kumar M. Y. Lau S. Lindgren L. A. Lowdermilk J. W. McGill C. J. McMillen R. E. Minkwitz, Sr. M. I. Mitelman E. T.
45、Norton D. E. Orten B. K. Pate1 G. Payerle P. A. Payne T. A. Prevost G. J. Reitter S. M. A. Rizvi M. P. Sampat H. J. Sim R. W. Simpson, Jr. M. R. Springrose W. W. Stein T. H. Stewart C. L. Stiegemeier R. W. Stoner R. A. Veitch L. B. Wagenaar F. N. Weffer R. J. Whearty R. C. Wicks D. J. Woodcock F. N.
46、 Young iv Copyright O 2000 IEEE. All rights reserved. -,-,- The following persons were on the balloting committee: Edward J. Adolphson Paul Ahrens D. J. Allan Jim Antweiler Jacques Aubin Donald E. Ballard Ron L. Barker Mike Barnes William H. Bartley Martin Baur Edward A. Bertolini Wallace B. Binder
47、Thomas E. Blackburn, III William E. Boettger Alain Bollinger Joe V. Bonucchi John D. Borst Alvaro Cancino W. J. Carter C. P. Caruso Donald J.Cash Jerry L. Corkran Domenico E. Corsi Bob Del Vecchio Dieter Dohnal J. C. Duart Richard F. Dudley Fred E. Elliott Keith Ellis D. J. Fallon R. H. Fausch P. T.
48、 Feghali Joe Foldi S. Foss Ron Fox Michael A. Franchek Ali A. Ghafounan Saurabh Ghosh Harry D. Gianakouros Donald A. Gillies James L. Goudie Richard D. Graham Blaine Gremillion Robert L. Grubb Robert L. Grunert Geoff H. Hall Ernst Hanique N. Wayne Hansen J. W. Harley James H. Harlow Robert H. Hartgr
49、ove R. R. Hayes William R. Henning K. R. Highton Peter J. Hoefler T. L. Holdway Philip J. Hopkinson Richard Huber James D. Huddleston, III A. F. Hueston Virendra Jhonsa Anthony J. Jonnatti Lars-Erik Juhlin Edward W. Kalkstein Gene Kallaur Joe J. Kelly Sheldon P. Kennedy Lawrence A. Kirchner Brian Klaponski Egon Koenig L. Koga Bann Kumar John G. Lackey Michael Y. Lau J. P. Lazar Singson Lee Frank A. Lewis Thomas Lundquist Joe D. MacDonald William A. Maguire Charles Mand
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